Paramagnetic Relaxation Enhancement Experiments: A Valuable Tool

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Paramagnetic Relaxation Enhancement Experiments: A Valuable Tool for the Characterization of Micellar Nanodevices Flore Keymeulen,† Paolo De Bernardin,†,‡ Antonella Dalla Cort,*,‡ and Kristin Bartik*,† †

Engineering of Molecular NanoSystems, Université libre de Bruxelles, 50 avenue F.D. Roosevelt, B-1050 Brussels, Belgium Department of Chemistry and IMC−CNR, Università La Sapienza, Piazzale Aldo Moro 5, 00185 Roma, Italy



S Supporting Information *

ABSTRACT: Micellar incorporation of hydrophobic molecular receptors is a promising strategy to obtain efficient nanodevices that work in water. In order to fully evaluate the potential of this approach, information on the localization and orientation of the receptor inside the micelle are necessary. Systematic studies undertaken on a uranyl−salophen receptor incorporated into CTABr and CTACl micelles show that nuclear magnetic resonance paramagnetic relaxation enhancement (NMR-PRE) experiments are particularly suitable to provide this type of information. The effect on the measurements of surfactant concentration, nature of the surfactant polar head, and ionic strength is also reported. Notably the normalization procedure applied to the obtained data can be considered of general application, thus enabling the comparison of information collected for different types of supramolecular micelle/receptor systems.



INTRODUCTION The development of molecular receptors able to recognize specific guests with high affinity and selectivity in organic media is a major topic in supramolecular chemistry. The possibility of using these receptors in an aqueous environment in order to detect physiologically important anions and pollutants species, although highly appealing, remains challenging. The first problem encountered in the majority of cases is the poor solubility of the receptors in water. A solution to this issue can be obtained through their incorporation into micelles to form water-soluble nanoscale devices.1−5 Micelles are extensively used to incorporate hydrophobic compounds in a wide variety of industrial and recovery processes as well as in an assortment of consumer products among which are pharmaceuticals.6−8 Micelles have also attracted interest in a more fundamental context where they are used as model membranes for the study of the interaction of various peptides, proteins, and organic molecules with lipid membranes.9−11 The potentialities and the straightforwardness of this strategy are manifest as no difficult and time-consuming synthetic modifications need to be brought to the receptor skeleton to make it hydrophilic. Moreover, the receptor/micelle system shows in many cases enhanced binding properties. For example, micellar incorporation of hydrophobic platinum porphyrins exhibit good oxygen sensitivity and response time.4 Another example is the one reported by Rebek and co-workers where the induced conformational reorganization of a resorcinarenecavitand incorporated into dodecylphosphocholine micelles significantly increases its binding capacity toward a series of different guests.2,12 We, too, have recently shown that the salophen-UO2 complex 1, shown in Figure 1, completely © 2013 American Chemical Society

Figure 1. Chemical structure and proton labeling of the uranyl− salophen receptor 1 and of surfactants CTAX (X = Br−, Cl−).

insoluble in water, exhibits very good binding affinity and selectivity for aqueous fluoride (K of the order of 104 M−1) if incorporated into cationic cetyltrimethylammonium bromide (CTABr) micelles.13 The observed affinity is 2 orders of magnitude larger than the one observed when the same receptor is made water-soluble by appending two glucose units on the ligand skeleton, confirming in this way the true supramolecular character of the micelle−receptor system.14 When trying to appreciate the full potential of this approach, information on the localization and orientation of molecular receptors within the micelle is of paramount importance. Nuclear magnetic resonance spectroscopy (NMR), through the monitoring of changes in the chemical shifts and relaxation Received: July 31, 2013 Revised: August 28, 2013 Published: September 5, 2013 11654

dx.doi.org/10.1021/jp4076367 | J. Phys. Chem. B 2013, 117, 11654−11659

The Journal of Physical Chemistry B

Article

where Iτ is the signal integral after a delay τ, I∞ is the signal integral after full relaxation, and α is the angle of inversion. The angle is left as a parameter in case of incomplete inversion. For each signal monitored, the increase in the longitudinal relaxation rate induced by the paramagnetic species (Δ(1/T1); the difference between the longitudinal relaxation rate measured in the presence and in the absence of the paramagnetic species) was plotted as a function of the concentration of paramagnetic species. A linear regression was undertaken with the experimental data points from which the relaxivity value was derived (slope of the line).

times of surfactant protons or via intermolecular surfactant− receptor NOEs, has proved to be efficient in this context yielding information on the loci of incorporated molecules in micelles.15−23 Paramagnetic relaxation enhancement (PRE) experiments can also be considered as an important NMR tool, which can be used to gain further information on these systems. To date, it has mainly been used to determine the position, orientation, and insertion depth of peptides in membrane-mimicking micelles,24−28 but as we show here, it can be applied also to much smaller systems. PRE experiments consist in the measurement of the increase in longitudinal or transverse relaxation rates induced by the presence of a paramagnetic species.29 The enhancement is distance dependent and can consequently provide information on the distance between the paramagnetic species and the nuclei under investigation. In the case of micelles, the paramagnetic species can either be specifically covalently bonded to the surfactant30−32 or can simply be a water-soluble probe, which remains in the solution surrounding the micelles.24,25,33 In our previous study devoted to the fluoride binding of receptor 1 incorporated into CTABr micelles, we mentioned some preliminary PRE experiments, which were confirmed by NOE measurements.13 Here, we report an extensive and systematic analysis of the effect of different parameters on PRE measurements carried out on cetyltrimetylammonium (CTAX) systems. We have considered the effect of the counterion (X = Cl, Br), of the ionic strength, and also of surfactant concentration. The study clearly points out that through a normalization procedure it is possible to compare data obtained for different systems in a reliable and meaningful way.



RESULTS AND DISCUSSION Micelles are characterized by size, shape, and aggregation number (number of surfactant molecules that compose the micelles, N) but also by the surfactant’s critical micellar concentration (the surfactant concentration above which the micelles can form; CMC). Surfactant molecules such as cetyltrimethylammonium bromide and chloride (CTAX; X = Br or Cl) ionize in aqueous solution, and the corresponding micelles are aggregates of CTA+ ions. The counterions that stay near the micellar surface do not fully neutralize the ammonium head groups, which bear a residual fractional charge equal to α. The values of the above-mentioned parameters for CTACl and CTABr micelles are given in Table 1. The differences in the Table 1. Micellar Parameters of 50 mM CTAX Solutions39

CTABr CTACl



EXPERIMENTAL SECTION Materials. Receptor 1 was synthetized as previously reported.34 K3[Cr(CN)6] (99.99% purity) was purchased from Aldrich and used without further purification. CTABr and CTACl surfactants were purchased from Aldrich and crystallized using standard procedures before use.35 D2O (99.9 atom %D) was purchased from Aldrich. Solutions of CTABr and CTACl were prepared by dissolving the surfactant in D2O. Then, 50 mM surfactant solutions containing receptor [1] (∼1 mM) were prepared by adding a known quantity of receptor, weighed with precision, to the surfactant solution and stirring for a minimum of 30 min. NMR Spectroscopy. All measurements were carried out at 30 °C in order to be above the Krafft temperature of both surfactants.36−38 1 H NMR spectra were recorded on a Varian spectrometer operating at 9.4 T (399.9 MHz for 1H). Amounts of 500 μL of the different solutions were placed in the NMR tube. For the PRE experiments, aliquots (∼5 μL) of a concentrated D2O solution of K3[Cr(CN)6] (2.7 mM) were added using micrometric Hamilton syringes. T1 measurements were undertaken using the classical inversion recovery (180−τ−90−acquisition) sequence, with 16 points and the delay varying between 0 and 6s. The delays were adapted according to the amount of added chromium salt. Data treatment was performed using the Varian VNMRJ software. To obtain the T1 values, eq 1 was adjusted to the values of the signal integrals Iτ = I∞[1 − (1 − cos α) e−τ / T1]

CMC (mM)

N

α

Semiminor axis b = c (Å)

Semimajor axis a (Å)

∼1 ∼1

145 107

0.26 0.28

24.0 23.0

33.7 27.1

size, shape, and charge of these two types of micelles can be explained by the fact that hydrated Cl− is larger than hydrated Br− and penetrates less into the Stern layer and is consequently less effective in neutralizing the head-groups.39 The assigned 1H NMR spectra of a 50 mM CTACl solution is shown in Figure 2. The spectrum of an analogous CTABr solution (not shown) is very similar, exhibiting only very small differences in chemical shifts (